Category: CHP

04 Jun

Village East Towers Gets Their Cogen Units Delivered

Bright Power CHP, Resiliency
Village East Towers receives their two 65 kW Capstone cogeneration units and backup generators. Generators are on the left and the cogeneration turbines are on the right.

 

Village East Towers (VET) had their two 65kW Capstone cogeneration units delivered the last week of May.

The project design pairs the two cogeneration units with backup generators for added resiliency. The cogeneration units will provide electrical and thermal energy savings for the residents along with backup power in the event of an electrical blackout.

Bright Power first began working with the board of VET, a 434-unit Mitchell-Lama multifamily residential cooperative located on East 10th Street and Avenue C, in 2016 to conduct a feasibility analysis. VET’s architect then hired Bright Power to provide Design and Implementation services to ensure project success. The scope of work also includes replacing some of the electrical infrastructures at the property.

Bright Power has been working with VET’s architects, contractors, and the board to complete the project – set to be completed later this summer. To help offset the cost of the project, the co-op received a $9.95 million federal resiliency grant from HUD that was locally administered by the HDC.

Read more about the exciting project here.

23 Mar

Even High-Efficiency Systems Need Tune-Ups: A Case for LL87

Punit Shah CHP, efficiency

Just because a building was built recently, or has “high-efficiency” equipment, does not mean that the building will actually be energy efficient.  In fact, often high-efficiency equipment and systems need more highly trained engineers, more rigorous maintenance, and more careful tune-ups in order to work their best. It’s kind of like the difference between doing a tune-up on a Prius versus the old stick-shift that your uncle could fix himself. What follows is the story of a decade-old building with some really big energy problems and some relatively simple fixes… once we figured out what was going on!

NYC’s Local Law 87: Energy Audits and Retro-commissioning

New York City’s Local Law 87 (LL87) has motivated and, in some cases, obligated building owners and operators to analyze the performance of their energy systems since its inception. However, the benefits of a retro-commissioning study are far greater than simply adhering to a compliance requirement.

If you are unfamiliar, LL87 requires all buildings in New York City that are larger than 50,000 square feet to perform an Energy Audit and Retro-commissioning Study every 10 years. This initiative gives building owners an opportunity to investigate and evaluate their building’s energy performance and address concerns with their major equipment.

As one of the leading LL87 service providers, Bright Power has come across several buildings where this compliance requirement has uncovered major issues with systems operation and overall efficiency. These audits have helped our clients dig deeper into their utility consumption, identify critical areas of concern, and discover opportunities to save energy and water. In many cases, we have uncovered solutions to improve the performance of major systems in the building and to address inefficiencies that would otherwise cost owners thousands of dollars more in utility spend.  

Beyond Compliance

We have observed that multifamily buildings with central hot water heating systems often illuminate the vast benefits of retro-commissioning projects. This is largely the case for heating systems that consist of a high-efficiency condensing boiler — and their issues can be compounded when the system includes a cogeneration (cogen) system. While these highly efficient systems are capable of realizing significant energy savings, they can only do so when they are designed, installed, and operated appropriately.

The most significant benefit of condensing boilers is their higher efficiency. This is achieved by recovering the latent heat from the exhaust gases and is predominantly dependent on the temperature of the return water served to the boiler as shown in the figure below. When the return water temperature rises above a certain temperature (120℉ in this instance), the boilers are no longer able to recover the latent heat, thereby losing their efficiency benefits. For this reason, it is imperative to accurately control the operation of these boilers to ensure the lowest return water temperature possible.

boiler efficiency graphy

Over the past few years, we have seen issues at over a dozen properties with nearly identical systems and operation parameters. In most cases, the condensing boilers were operating such that they were incapable of taking advantage of higher overall efficiency.  What started as a compliance-driven study in these buildings became much more, delivering real value to the owner and residents.

Condensing Boilers and Cogeneration System: A Case Study

Here is an example of an LL87 audit we performed on a 10-year-old building where we encountered issues with the operation and efficiency of the heating system. This building is representative of a typical high-efficiency heating system that includes condensing boilers and a cogen unit. On paper, this building should be fairly energy efficient considering the age and equipment. However, that was not the case. It is likely the building owner would not have considered performing an energy audit had it not been mandated by LL87.

Building Type: Multifamily Rental
Location: NYC Metro
Built: 2008
Major Mechanical Systems: Condensing Boilers and Cogeneration System
Client Concerns: High utility consumption and spend
Client Engagement: Local Law 87 Energy Audit and Retro-commissioning Study

We started our analysis by benchmarking energy and water data for the property in our EnergyScoreCards platform. We immediately saw red flags. The first of which was the property’s Energy Use Index (EUI): it was more than double the national average for multifamily buildings. And when compared to buildings in New York City, the EUI was in the bottom 50% among buildings of similar age and occupancy.

Through our analysis, we discovered some major issues with the operation and control strategy of the heating system. Most importantly, we found problems with the integration and controls of the heating and cogeneration systems – the biggest reason why the building had a significantly higher energy usage.

Typically, a majority of these issues are discovered and addressed during the commissioning phase of construction, but, unsurprisingly, we learned that this system was never commissioned upon installation. Some of the most critical issues observed with the systems include:

  • The cogen unit was operating at all times, regardless of the thermal or electric loads, resulting in excess natural gas usage.
  • The cogen unit was isolated from the heating system, effectively reducing the cogen unit to an inefficient and very expensive natural gas generator, basically negating the benefits of the plant.
  • The boilers were operating throughout the year to provide heating and domestic hot water (DHW) because the cogen was not being utilized as intended.
  • While the DHW setup was installed in the boiler room, the piping was set up so that the heated hot water had to travel through the whole building before going to the DHW system located right next to the boilers.  
  • The boiler controller did not have any feedback from the DHW setup, resulting in the boilers operating continuously regardless of the loads.
  • The controls setpoints were overridden to provide high-temperature hot water all year round to the DHW system. The high water temperature yields significantly lower boiler efficiency thereby reducing the advantages of condensing boilers.

Recommended Solution

Based on our findings, it was clear that the recommendations needed to comprehensively target the distribution and controls for the system. In order to resolve these issues, we recommended these measures:

  • Reconfigure the current piping setup to integrate the cogen thermal output into the heating system loop. This would ensure the cogen plant would work as it was originally designed, not as a natural gas generator.
  • Reconfigure the distribution system to direct heated water straight to the DHW setup, rather than loop through the whole building before reaching its intended destination.
  • Upgrade the existing controller to one capable of integrating the boiler, DHW setup, and the cogen unit. Install temperature sensors on DHW tanks and provide an input to the new controller. This would allow the building to change its operations based on the weather and season. It would also allow the boilers to operate at higher efficiency in the absence of a DHW demand.
  • Install cogen unit controls to optimize its operation based on either the electric or thermal load.

Implementing these recommendations is expected to resolve the existing issues with the operation and overall efficiency of the system. Based on our energy modeling, the measures listed above will reduce the building’s energy usage overall by over 35% per year. This would place the building in the top 25% for buildings in its category in the City. Paired with other measures recommended as part of the study, the building’s overall energy usage could be reduced by half and have an expected simple payback of less than 5 years.

This project illustrates the potential benefits a qualified retro-commissioning agent can provide. Through retro-commissioning studies, property owners not only comply with City law, but also create energy-saving projects that have long-lasting impacts on the efficiency, operation, and maintenance of their buildings’ systems. In many cases, the savings generated from finding and fixing critical issues and their root causes have been significantly greater than the cost of performing the audit and retro-commissioning study.

Do you have similar systems in your building and have concerns about their efficiency? Is your building performing similarly? Contact us and we’ll find the root cause of your issue!

 


 

Sources:

  • LAARS Heating Systems 6000 Condor Drive  Moorpark, CA 93021 ©LAARS Heating Systems 0409 Document 1183C
  • One City Built to Last TRANSFORMING NEW YORK CITY BUILDINGS FOR A LOW-CARBON FUTURE – Technical Working Group Report by The City of New York
14 Jan

New Incentives for CHP

Jesse Petersen BQDM, CHP, ConEd, energy management

CHP has never been a better deal in NYC!  Con Edison is partnering with the New York State Energy Research and Development Authority (NYSERDA) to reduce electric demand in parts of Brooklyn and Queens (BQDM) by deploying a series of combined heat and power (CHP) projects. Even more exciting is that, for a limited time (applications are due February 29th, 2016), Con Edison and NYSERDA together will pay for up to 100% of project cost. Sounds great, but how do you get in? Let’s break it down.

What is BQDM?

bqdm 2

Brooklyn Queens Demand Management, or BQDM, is a Con Edison initiative put in place to reduce the electricity demand in specific Brooklyn and Queens neighborhoods. See above map.  To delay building a new substation to meet growing electricity demand, Con Edison is providing a series of initiatives to reduce electricity usage during peak times.

Why CHP?

In short, it’s extremely efficient. Combined heat and power (CHP) or ‘cogeneration’ is a way of producing electricity and useful heat, at the same time. A CHP system consists of a natural gas-fired electric generator, plus a system to capture the heat that is always produced and typically lost, and put it to productive use.  The heat can be used for heating domestic hot water, hydronic and warm air heating and even, in some cases, air-cooling.  The CHP systems we recommend always provide back-up power (or “black-start”) during grid outages.

Plus, it’s extremely cost-effective. The electricity produced by a CHP system is directly related to the cost of natural gas, without any of the charges for electricity distribution that you pay for conventional utility power.  While an electric generator can reach a maximum of 45% efficiency, a CHP system with heat recapture can reach 80% efficiency.  The result is an electricity price of 8 cents per kWh throughout the lifetime of a CHP system.

Furthermore, running the CHP system during summer days relieves stress on the grid, lowers peak demand and reduces overall fuel consumption.      

How do I know if I’m eligible?

Just ask! Bright Power can verify your building’s eligibility for this program. We will help you evaluate your building based on the program’s criteria:

  • significant annual energy consumption for both electricity and heat (e.g. an electric utility bill of $5,000 or more per month and a gas bill of $3,500 or more)
  • access to natural gas (to be confirmed by National Grid)
  • sufficient space to accommodate a CHP system with reasonable access to electricity and natural gas infrastructure (typically a minimum of 200 square feet)

Our team of energy experts are available to go over these requirements with you to see if your building is a good fit for the program.  Don’t hesitate to reach out – the time is now!